DE19907319A1 - Snubber - Google Patents

Abstract

The invention relates to a surge protection element (1) with direct signaling, comprising a three-pole surge arrester (2), a fail-safe contact (3) and a signaling contact (5), the center electrode (18) of the surge arrester (2) being permanently connected to a Ground potential is connected, the fail-safe contact (3) is formed with at least one fusible element (4) and can be resiliently biased onto the surge arrester (2), the fusible element (4) being located on insulated areas (17) of the surge arrester (2) rests, and the signaling contact (5) is permanently connected to the fail-safe contact (3), and a fail-safe contact (3) for use in an overvoltage protection element (1).

Description

The invention relates to an overvoltage protection element according to the Preamble of claim 1.

Especially in telecommunications and data technology Surge protection elements used to the appropriate Twin wires before overvoltages and currents due to technical Defects or external disturbances such. B. Protect lightning strikes. To such surge protection elements have a voltage-limiting and usually also a current-limiting component on which a Melting element, usually in the form of a solder pill, is assigned. Occurs in the voltage-limiting component for a long time Overcurrent, the solder pill melts due to the occurring Heat loss at the component, which usually results in a mechanical failure Safe short-circuits the lines to earth. This is necessary because of the resulting overcurrents the components and their immediate surroundings functionality may have been impaired. For simpler Identification of which fail safes have been triggered are already Various optical fail-safe signaling known for example, LEDs are used.

There are various ways to signal the triggering of a fail-safe Known solutions. If the voltage limiting overheats Component can in addition to the short circuit of a and b to earth Triggering a parallel process (indirect Signaling). The safety-relevant process of fail-safe triggering remains completely unaffected by the signaling process, is disadvantageous but the only approximate connection. Even with optimal Coordination of both processes are always thermal constellations possible where the fail-safe has triggered but the signaling has not takes place or vice versa.  

For direct signaling, it is known to use the spring-loaded Plug the fail-safe contact onto the surge arrester which is to be used one via a melting element and the other directly with one Center electrode of the surge arrester is connected. The The center electrode is also permanently connected to the via a solder joint Earth potential connected, so that the fail-safe contact is also permanent is connected to the earth potential. Furthermore, the fail-safe contact formed with a clamp that, for example, in a circuit board is insertable. The clamping causes an adjustment between Surge arrester and fail-safe contact or signaling contact and surge arrester. The signaling contact is in the same Direction like the fail-safe contact is spring-loaded and lies over one insulating film on the melting element. The signaling contact is below the melting element with a hook-shaped bulge formed, the when melting the melting element Signaling contact below the insulating film electrically with the Fail-safe contact and thus connected to the earth potential. This will the electrical circuit of the fail-safe signaling is closed, and for example an LED starts to light up. This well known Surge protection element, however, has some disadvantages. The Surge arrester and fail-safe contact are in balance, that is disturbed by the additional bias of the signaling contact is so that the surge arrester can be displaced under load can. Another problem is the complex manufacture of the insulating Foil for the signaling contact. Furthermore, the positioning between the surge arrester and the fail-safe contact via the Clamping or between fail-safe contact and signaling contact quite complex and prone to errors, since only an exact relative movement between fail-safe contact and signaling contact an error-free Signaling guaranteed.

DE 197 08 651 A1 describes a gas-filled surge conductor at least two electrodes and with one between two electrodes  arranged isolator and with an overload protection in the form of a known external short-circuit device, in which the short-circuit device protrudes axially above the surge arrester and for this purpose from an electrical conductive, running in the axial direction of the surge arrester Short-circuit bracket, the ends of which by means of a spring force exercising holding device and one fusible when heat is supplied Spacer is held at a radial distance from the electrodes, wherein the holding device from a snapped onto the insulator open ring made of a strip-shaped, resilient material one end of the shorting bar is arranged, the Spacers either between the middle part of the shorting bar and the insulator or between the ends of the shorting bar and the each electrode is arranged. A disadvantage of the known Surge arrester is next to a lack of signaling that at a three-pole design, the two a, b lines separated be short-circuited.

The invention is therefore based on the technical problem Surge protection element with direct signaling to create that is easier to manufacture and position and is reliable Signaling realized, as well as to create a fail-safe contact for such an overvoltage protection element can be used.

The solution to the technical problem results from the characteristics of Claims 1 and 6. Further advantageous embodiments result from the subclaims.

A fusing element is placed on the insulating parts of the Surge arrester arranged and the signaling contact permanently electrically connected to the fail-safe contact. This eliminates the difficult to set relative movement between fail-safe contact and signaling contact. Another advantage is that the Signaling contact no insulating film or the like is required.  

If, for example, the permanent connection between fail-safe Contact and signaling contact by a resilient bias of the Signaling contact against the fail-safe contact can be realized nevertheless the problem of displacement of the surge arrester prevent since the bias of the signaling contact is not in the must be in the same direction as the fail-safe contact, as long as only it is ensured that the two are permanently electrically connected, so that the bias of the signaling contact is not that Balance on the surge conductor disturbs, so that it does not displace can be. Furthermore, clamping can also be dispensed with what simplifies manufacture and positioning. Then kick one longer-term overvoltage, the melting element melts, and the Shorting bar short-circuits the electrodes of the surge arrester. At the same time, the fail-safe contact touches the center electrode and is thereby connected to the earth potential.

In a further preferred embodiment, the fail-safe contact is on another side of the shorting bar Melting element designed with an associated earth contact. At the When the melting elements melt, the earth contact contacts the Center contact of the surge arrester safely before the shorting bar shorts the electrodes. This will always counter the electrodes Earth shorted.

In a further preferred embodiment, the melting elements designed as a solder bridge. This allows the fail- Safe contact, so that both electrodes are safe at the same time be short-circuited.

In a further preferred embodiment, the fail-safe contact is in the middle area formed with support elements, which preferably from the Fail-safe contact are cut out. The support elements prevent the fail-safe contact is pushed too far onto the surge arrester  is and acts like an adjustment element that ensures the safe contact of Guaranteed solder bridge and surge arrester.

In a further preferred embodiment, the longitudinal dimensions are of the fail-safe contact in the middle area is equal to that of the Surge arrester, which allows simplified visual control, whether the fail-safe contact is symmetrical on the surge arrester is postponed and a simple shift of the fail-safe contact prevented.

The invention is based on a preferred Embodiment explained in more detail. The figure shows:

Fig. 1 is a side view of a schematic diagram of a surge element,

Fig. 2 is a side view of a surge arrester with deferred fail-safe contact,

Fig. 3 shows a cross-section through the surge arrester with deferred fail-safe contact,

Fig. 4 is a perspective view of the surge arrester with a fail-safe contact and

Fig. 5 is a side view of a schematic diagram of an overvoltage element for a relative movement between the fail-safe contact and signaling contact (prior art).

FIG. 5 shows an overvoltage element 1 according to the prior art, which is first briefly described to illustrate the invention. The overvoltage protection element 1 comprises an overvoltage arrester 2 , a fail-safe contact 3 , a fuse element 4 and a signaling contact 5 . A center electrode of the surge arrester 2 is permanently connected to an earth rail 7 via a solder joint 6 . The melting element 4 is also connected to the center electrode of the surge arrester 2 . The fail-safe contact 3 is thus also permanently at ground potential via the melting element 4 . Part of the fail-safe contact 3 is inserted into the earth rail 7 and forms a clamping 8 . The signaling contact 5 is arranged on a circuit board 9 and is part of a signaling circuit. The signaling contact 5 is like the fail-safe contact 3 resiliently biased and is electrically insulated in the region of the fusible element 4 by means of an insulating film with respect to the fusible element. 4 When the melting element 4 melts, there is a relative movement between the fail-safe contact 3 and the signaling contact 5 , the two being connected to one another below the insulating film by a bulge 10 , so that the signaling circuit is closed.

In principle, the surge protection element 1 according to the invention is shown in FIG. 1. As in the prior art according to FIG. 5, the center electrode of the surge arrester 2 is permanently connected to the earth rail 7 , for example via a solder joint 6 . The fail-safe contact 3 is spring-loaded snapped onto the surge arrester 2 . In contrast to the prior art, the fuse element 4 connected to the fail-safe contact 3 is not connected to the central electrode of the surge arrester 2 , but rests on the insulated areas of the surge arrester 2 between the electrodes. The signaling contact 5 is resiliently biased in the direction of the printed circuit board 9 and is connected in an electrically conductive manner to the fail-safe contact 3 . When the melting element 4 melts, the fail-safe contact 3 moves onto the center electrode of the surge arrester 2 , so that the fail-safe contact 3 is connected to the ground potential when there is a contact. As a result, the signaling contact 5 , which is permanently electrically connected to the fail-safe contact 3, is also connected to the ground potential, so that the signaling circuit is closed. The bias of the signaling contact 5 , which no longer has the same direction as the bias of the fail-safe contact 3 as in the prior art, only has to ensure that when the fail-safe contact 3 moves, the signaling contact 5 with the fail - Safe contact 3 remains electrically connected. However, this is much easier to set than a specific relative movement as in the prior art. Another advantage is that the force of the signaling contact 5 on the surge arrester 2 is substantially perpendicular to the earth rail 7 , so that the surge arrester 2 is not displaced. At this point, it should be expressly noted once again that, if necessary, a bias of the signaling contact 5 can even be dispensed with entirely, as long as it is only ensured that despite a movement of the fail-safe contact 3, the latter remains permanently connected to the signaling contact 5 ,

The fail-safe contact 3 comprises a short-circuit area 11 , a central area 12 and an earth contact area 13 and is formed from a strip-shaped, resilient, electrically conductive material in the form of an open ring. In the short-circuit area 11 , the fail-safe contact 3 is formed with a short-circuiting bracket 14 which is intended to short-circuit the two electrodes 15 , 16 of the surge arrester 2 in the event of thermal overload. The fuse element 4 assigned to the shorting bar 14 is in the form of a solder bridge, which rests on the insulated areas 17 next to the center electrode 18 on the surge arrester 2 . In the earth contact area 13 , the fail-safe contact 3 is formed with an earth contact 19 in the area of the center electrode 18 , the earth contact 19 preferably being realized by a suitable free cut. A fusible element 20 designed as a solder bridge, which also rests on the insulated areas 17, is also assigned to the earth contact 19 . In the central area 12 , the fail-safe contact 3 is formed with support elements 21 which, in the snap-out state, rest on the isolated areas 17 of the surge arrester 2 and are also realized by free cuts. The support elements adjust the solder bridges so that they do not come to rest on the center electrode 18 .

If there is a longer overvoltage with a thermal load associated with it, the melting elements 4 , 20 begin to melt, which results in a movement of the fail-safe contact 3 in the earth contact area 13 and in the short-circuit area 11 . Due to the inward formation of the earth contact 19 , it first touches the center electrode 18 , so that the fail-safe contact 3 is at earth potential. As it melts further, the shorting bar 14 then touches the two electrodes 15 , 16 and short-circuits the lines connected to them to earth. This ensures that the lines are always short-circuited to earth. The formation of the fusible elements 4 , 20 as solder bridges ensures that even with only one-sided overvoltage, for example on the a-line, both electrodes 15 , 16 and thus the a- and b-line are safely short-circuited to earth, because of the heat conduction the melting element 4 , 20 melts completely. In the central area 12 , the longitudinal dimension of the fail-safe contact 3 is the same as that of the surge arrester 2 , which enables simple optical checking of the correct snapping on.

LIST OF REFERENCE NUMBERS

1

Snubber

2

Surge arresters

3

Fail-safe contact

4

fuse

5

signaling contact

6

soldered point

7

Earth bar

8th

clamping

9

circuit board

10

bulge

11

Short range

12

middle area

13

Erdkontaktbereich

14

Shorting bar

15

electrode

16

electrode

17

isolated area

18

center electrode

19

ground contact

20

fuse

21

support element

Claims (7)

1. Surge protection element with direct signaling, comprising a three-pole surge arrester, a fail-safe contact and a signaling contact, the center electrode of the surge arrester being permanently connected to a ground potential, the fail-safe contact being designed with at least one melting element and being spring-loaded the surge arrester can be plugged on, characterized in that the melting element ( 4 ) rests on insulated areas ( 17 ) of the surge arrester ( 2 ), and the signaling contact ( 5 ) is permanently connected to the fail-safe contact ( 3 ). 2. Surge protection element according to claim 1, characterized in that the fail-safe contact ( 3 ) with a second melting element ( 20 ), which is associated with an earth contact ( 19 ), is formed. 3. Overvoltage protection element according to claim 1 or 2, characterized in that the melting element or elements ( 4 , 20 ) are designed as a solder bridge. 4. Surge protection element according to one of the preceding claims, characterized in that in a central region ( 12 ) the fail-safe contact ( 3 ) is formed with support elements ( 21 ) which on the insulated areas ( 17 ) of the surge arrester ( 2 ) lie on when plugged in. 5. Surge protection element according to one of the preceding claims, characterized in that the longitudinal dimension of the fail-safe contact ( 3 ) in the central region ( 12 ) is equal to that of the surge arrester ( 2 ). 6. Fail-safe contact for use in a surge protection element, made of a strip-shaped, resilient, electrically conductive material in the form of an open ring, at one end of which a short-circuiting bracket is arranged, to which a spacer designed as a melting element is assigned on the inside, thereby characterized in that the melting element ( 4 ) is designed as a solder bridge. 7. Fail-safe contact according to claim 6, characterized in that a second solder bridge with an associated earth contact ( 19 ) is arranged on the opposite end of the shorting bar ( 14 ).